Enhancement of low-speed piezoelectric wind energy harvesting by bluff body shapes: spindle-like and butterfly-like cross-sections
Enhancement of low-speed piezoelectric wind energy harvesting by bluff body shapes: spindle-like and butterfly-like cross-sections
Fluid-structure interaction can be utilized to harvest the low-speed wind energy for sustaining the low-power sensors for structural health monitoring. To enhance the low-speed wind energy harvesting, this study proposes the novel spindle-like and butterfly-like bluff bodies by coupling both the vortex-induced vibration (VIV) and galloping phenomena. Comprehensive wind tunnel experiments are conducted to investigate the advantages of the two bluff bodies in terms of the bluff body cross-sections and installment directions. The experimental results demonstrate that for both the spindle-like and butterfly-like bluff bodies, the vertical installment and small width ratio are beneficial to the performance in a broad range of wind speeds. Compared to a conventional galloping-based energy harvester, owing to the coupling between the VIV and galloping, the vertical spindle-like bluff body with the smallest width ratio can reduce the threshold wind speed of activating the energy harvesting function by over 13%, and improve the maximum voltage output by over 160%. Finally, taking the spindle-like bluff body as an example, the computational fluid dynamics (CFD) studies are conducted by using XFlow software to interpret the physical insight of performance enhancement. The CFD results show that the vertical installment direction and a small width ratio play an important role. The two designs can lead to a stronger aerodynamic force due to the fast vortex shedding, which improves the energy conversion efficiency from the flow-induced vibrations.
Bluff-body design, Flow-induced vibration, Energy harvesting, VIV, Galloping
Wang, Junlei
7afcea11-129b-4a82-b572-95b443c2c643
Zhang, Chengyun
b88ca974-9527-4ccf-a26e-c10d9c02480a
Gu, Shanghao
39fe3426-254d-462f-9a02-bdc79a40bec0
Yang, Kai
a23af03e-4020-4c3d-9fdf-902827fa19d7
Li, Hang
1fbf81bb-5cab-4e4a-9ce0-f464d7802bb3
Lai, Yuyang
cb5e4875-bf1f-4277-98a6-b847d6ef792f
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
1 August 2020
Wang, Junlei
7afcea11-129b-4a82-b572-95b443c2c643
Zhang, Chengyun
b88ca974-9527-4ccf-a26e-c10d9c02480a
Gu, Shanghao
39fe3426-254d-462f-9a02-bdc79a40bec0
Yang, Kai
a23af03e-4020-4c3d-9fdf-902827fa19d7
Li, Hang
1fbf81bb-5cab-4e4a-9ce0-f464d7802bb3
Lai, Yuyang
cb5e4875-bf1f-4277-98a6-b847d6ef792f
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Wang, Junlei, Zhang, Chengyun, Gu, Shanghao, Yang, Kai, Li, Hang, Lai, Yuyang and Yurchenko, Daniil
(2020)
Enhancement of low-speed piezoelectric wind energy harvesting by bluff body shapes: spindle-like and butterfly-like cross-sections.
Aerospace Science and Technology, 103, [105898].
(doi:10.1016/j.ast.2020.105898).
Abstract
Fluid-structure interaction can be utilized to harvest the low-speed wind energy for sustaining the low-power sensors for structural health monitoring. To enhance the low-speed wind energy harvesting, this study proposes the novel spindle-like and butterfly-like bluff bodies by coupling both the vortex-induced vibration (VIV) and galloping phenomena. Comprehensive wind tunnel experiments are conducted to investigate the advantages of the two bluff bodies in terms of the bluff body cross-sections and installment directions. The experimental results demonstrate that for both the spindle-like and butterfly-like bluff bodies, the vertical installment and small width ratio are beneficial to the performance in a broad range of wind speeds. Compared to a conventional galloping-based energy harvester, owing to the coupling between the VIV and galloping, the vertical spindle-like bluff body with the smallest width ratio can reduce the threshold wind speed of activating the energy harvesting function by over 13%, and improve the maximum voltage output by over 160%. Finally, taking the spindle-like bluff body as an example, the computational fluid dynamics (CFD) studies are conducted by using XFlow software to interpret the physical insight of performance enhancement. The CFD results show that the vertical installment direction and a small width ratio play an important role. The two designs can lead to a stronger aerodynamic force due to the fast vortex shedding, which improves the energy conversion efficiency from the flow-induced vibrations.
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More information
Accepted/In Press date: 7 May 2020
e-pub ahead of print date: 5 June 2020
Published date: 1 August 2020
Keywords:
Bluff-body design, Flow-induced vibration, Energy harvesting, VIV, Galloping
Identifiers
Local EPrints ID: 469718
URI: http://eprints.soton.ac.uk/id/eprint/469718
ISSN: 1270-9638
PURE UUID: 3d18ea95-b421-4d8d-bec8-528620b64609
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Date deposited: 22 Sep 2022 17:06
Last modified: 17 Mar 2024 04:11
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Contributors
Author:
Junlei Wang
Author:
Chengyun Zhang
Author:
Shanghao Gu
Author:
Kai Yang
Author:
Hang Li
Author:
Yuyang Lai
Author:
Daniil Yurchenko
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